Infrared ray irradiation apparatus and infrared ray irradiation source used therein

ABSTRACT

An infrared irradiation source of an infrared irradiation apparatus is provided. The infrared irradiation source is comprised of a heat generator and an infrared ray irradiation member for being heated by the heat generator and emitting far infrared rays not containing near infrared rays of wavelength less than 4 μm, wherein the heat generation rate by the heat generator is designed to be greater at the circumferential portion than at the central portion of the far infrared irradiation member. Preferably, the infrared irradiation source should be provided in a plurality of numbers so as to emit far infrared rays of wavelength ranging from 5 to 20 μm to the periphery of the human body accommodated in a space formed by the human body mounting portion and the operable cover portion of the apparatus.

BACKGROUND OF THE INVENTION

1. Field of the Invention

The present invention relates to an infrared ray irradiation apparatusand infrared ray irradiation source used therein, and more specificallyto an infrared ray irradiation apparatus and infrared ray irradiationsource used therein for treating diseases, particularly malignanttumors, viral diseases by irradiating with far-infrared rays and raisingthe intracorporeal temperature.

2. Description of the Prior Art

Hitherto, for malignant tumors such as cancers, sarcoma, etc.,treatments including abscission by operations, irradiation ofradioactive ray, administration of drugs, etc. have been given, buttumors which have metastasized are difficult to treat. Even those at theinitial stages, operations and other methods may cause excessively largeburdens to the human body, lower the immunological competence, and haveproblems of recurrence of tumors, occurrence of other diseases, etc.Viral diseases are unable to be treated unless suitable vaccine ispresent, and such is the state of things that there is no effectivetreatment when people are infected with AIDS virus, etc.

Because in recent years, it has been found that malignant tumors andviruses die out or are inactivated when heated to temperatures exceeding41° C., hyperthermia has attracted keen attention, and treatments forimmersing patients in warm water or methods for irradiating withinfrared rays have been developed, and infrared ray irradiationapparatus have begun to be fabricated.

However, since the treatment by immersing patients in warm water isachieved by thermal conduction from the human body surface, long time isrequired for heating the inside of human body, weighing too much on thehuman body. In addition, the infrared ray irradiation source used forinfrared ray irradiation apparatus which have been fabricated andcommercially available to date are said to be far infrared rayirradiation source, but in actuality contain a large volume of nearinfrared rays and has a construction in which the infrared rayirradiation source is formed in a single unit. Near infrared rays havelarge energy and provide low permeability to human body, and requirelong time to heat the depth of the human body, and patients must beanesthetized for treatment in order to prevent patients from moving. Inaddition, because the human body is exposed to infrared ray irradiationsource containing near infrared rays for a long time, the energy appliedto the body surface increases, and a problem of low-temperature burnsoccurs, and in order to reduce this problem, an expensive control meansmust be provided.

In view of the foregoing, it is the main object of this invention toprovide an infrared ray irradiation apparatus and infrared rayirradiation source used therein which allow far infrared rays to reachthe depth of the human body in a short time, enables optional setting ofirradiation intensity for each portion of human body without generatinglow-temperature burns in patients, and can irradiate far infrared raysonly.

SUMMARY OF THE INVENTION

In order to achieve the above-mentioned object, the infrared rayirradiation apparatus according to the present invention comprises ahuman body mounting portion, an operable cover portion comprisingexterior members, interior panels, and members containing fillingmaterial between these, and infrared ray irradiation source, whereinthis infrared ray irradiation source is arranged more than one toirradiate with far infrared rays not containing near infrared rays withless than 4 μm wavelength, and the periphery of the human bodyaccommodated in a space formed by the human body mounting portion andthe cover portion is irradiated with far infrared rays.

It is desirable that the said operable cover portion is designed to be asemi-cylindrical form.

It is desirable that the infrared ray irradiation sources arranged morethan one radiate far infrared rays of wavelength from 5 to 20 μm, moresuitably from 8 to 15 μm. When the wavelength of far infrared raysradiated from the infrared ray irradiation apparatus is short wavelengthof 5 to 20 μm, the temperature of each portion of the body is uniformlyraised to the range required for treatment of diseases and is free oflocalized or excessive temperature rise. In addition, the energy appliedto the human body surface does not rise as is the case when the infraredray irradiation source containing near infrared rays is used, andconsequently, there is no fear of generating low-temperature burns byheating the human body surface portion. And as a result of the wholehuman body heated uniformly, a control for measuring temperature of eachbody portion and feeding back the data are no longer required or can besimplified. In addition, the far infrared rays of long wavelength reachthe depth of the human body, enabling treatment in a short time.Consequently, there is no need for anesthetizing patients beforeirradiation for treatment, and low-cost and safe treatments can beachieved.

In the case of this invention, since more than one said far infrared rayirradiation sources are arranged, it is possible to set radiationintensity for each irradiation source, and at the required portion, forexample, where the distance from the affected portion or body surface tothe central portion is large, the radiation intensity can be set highand irradiation time can be set long, and for other portions,irradiation can be set weak and short. Consequently, the use of theapparatus according to this invention no longer requires an expensivecontrol as required by the conventional apparatus.

The other characteristic of this invention is that the far infrared rayirradiation source is installed to the human body mounting surface as inthe case of interior panel. With this configuration, it is possible toirradiate the human body with far infrared rays from the overallperiphery without rotating the human body during treatment, whichcontributes to uniform and rapid heating of whole human body and enablesshortening of treatment time.

For the far infrared ray irradiation source used for this invention, itis preferable to arrange more than one sources whose size is smallerthan that of the said human body mounting portion and interior panel.For the shape, circular, rhombic, square, and other various shapes canbe used and are not particularly limited, but in view of the ease offabrication and arrangement, the irradiation source with a rectangularradiation surface is preferable.

The far infrared ray irradiation source used for this invention has aconstruction with an inorganic-system material layer generating farinfrared rays mounted on the heater surface, and for such inorganicsystem materials, alumina system, zirconia system, etc. are known andapplicable.

This kind of infrared ray irradiation sources are preferably arrangedmore than 11. This is because when the number is small, it is unable tosuccessfully control temperature of each body portion.

The infrared ray irradiation sources are preferably arranged more than 3rows particularly in the length (height) direction of the human body andmore than 2 rows in the circumferential direction. In particular, thenumber of rows of infrared ray irradiation sources arranged in thecircumferential direction is preferably increased for the breast and theabdomen, and reduced for the leg portion. For the leg portion, it isdesirable to irradiate the leg portion with infrared rays also from thesole of the foot, and consequently, it is preferable to provide aninfrared ray irradiation source on the sole side.

It is preferable to separate and space these plurality of infrared rayirradiation sources with aluminum reflection plates. Aluminum provideshigh reflection efficiency of far infrared rays and even when the sameinfrared rays irradiation sources are used, irradiation and treatment ofbetter efficiency can be carried out.

In this invention, it is preferable to install a fan for ventilating andfluidizing the air layer in the said space portion. Because installingthis fan can control the atmosphere around the human body comparativelyuniformly and the surface portion can be set to low temperature with theinside temperature of the human body maintained high by irradiation offar infrared rays, burden to the patient can be reduced. Furthermore,humidity of the atmosphere around the human body can be controlled byventilation and it is possible to freely set the low-humidity andhigh-humidity condition, thereby improving the treatment effects.

In addition, the other characteristic of the far infrared irradiationsource according to this invention lies in that the irradiation sourcehas a heat generator and an infrared ray irradiation member heated bythis heat generator for radiating far infrared rays free of nearinfrared rays of wavelength less than 4 μm, and is designed to allow theheat generator to generate more heat at the peripheral portion ratherthan at the central portion of the infrared ray irradiation member.

With this configuration, the heating calorie at the peripheral portionwith larger heat dissipation than at the central portion with less heatdissipation increases for the infrared ray irradiation member, and as aresult, the temperature distribution of the infrared ray irradiationmember becomes uniform, and far infrared rays can be radiated uniformlyfrom the whole surfaces of the infrared ray irradiation member.

According to this invention, a far infrared ray irradiation source whichcan radiate only far infrared rays desirable for hyperthermia from theinfrared ray irradiation members can be provided.

It is preferable that the said heat generator is composed with heatingwires, and the installation density of the said heating wires isdesigned to be higher at the peripheral portion than at the centralportion of the said infrared ray irradiation member.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a whole view schematically showing the infrared rayirradiation apparatus;

FIG. 2 shows the space for accommodating a human body and irradiatingthe human body with far infrared rays as seen from the head direction ofthe human body;

FIG. 3 shows one example of arrangement of a human body and heaters;

FIG. 4 shows one example of heaters arranged on the interior panel;

FIG. 5 is a cross-sectional view of the other embodiment of the farinfrared ray irradiation source used for the infrared ray irradiationapparatus according to this invention; and

FIG. 6 is a top view partly broken away of the far infrared rayirradiation source shown in FIG. 5.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS

Referring now to drawings, there are shown preferred embodiments of theinfrared ray irradiation apparatus according to the present invention.

This infrared ray irradiation apparatus comprises a cover portion 1 anda bed portion 2. This bed portion 2 further comprises a human bodymounting portion 3 and a base portion 4 for accommodating the human bodymounting portion 3. The said cover portion 1 has a semi-cylindricalform, and a space 5 is formed for accommodating the human body by thehuman body mounting portion 3 and the cover portion 1. The base portion4 can accommodate a power supply portion, a control portion, a devicefor monitoring and displaying patient condition, an oxygen supplyingapparatus, etc. inside. The cover 1 can be opened and closed foraccommodating and diagnosing the patient as well as installing necessarysensors. In addition, as shown in FIG. 3, it is preferably designed toopen and close the end portion in the human body leg direction as anaxis. It may be opened and closed by mechanical action using hydrauliccylinders, etc. or electrically or manually.

Next discussion will be made on the main apparatus portion forirradiating the human body with far infrared rays using this apparatusand carrying out treatments of diseases, etc.

This portion has a nearly flat human body mounting portion 3 for forminga space 5 to accommodate the lying human body and a semi-cylindricalcover portion 1 arranged around the human body. The space 5 foraccommodating the human body is nearly semi-cylindrical, with one endequipped with a head portion isolating cover 9 which isolates the space5 from the outside at the neck portion of the human body. To the legside of the human body, a leg portion isolating cover 11 is installed.Of the said cover portion 1, on the side facing the space 5 of the humanbody mounting portion 3 and the cover portion 1, a plurality of infraredirradiation sources 7 (7a-7e) are placed for irradiating far infraredrays not containing near infrared rays of wavelength less than 4 μm asshown in FIG. 4. The space 5 is designed with various sizes of thepatient as well as the motion of the patient inside taken into account.If the human body surface is too distant from the infrared rayirradiation source, attenuation of far infrared rays increases.

The cover portion 1 comprises an exterior member 6a, interior panel 6c,and material containing filling member 6b placed in-between as shown inFIG. 2. The filling material 6b is preferably heat-insulating material.On the interior panel 6c, the infrared ray irradiation source is placedin such a manner that the irradiating surface sufficiently faces thehuman body. The power supply cord connected to the infrared rayirradiation source 7 is preferably installed in the heat-insulatingmaterial layer and connected to the power supply portion and controlportion.

The head isolating cover 9 is installed to the cover portion 1 free toopen and close, and even if any unforseeable incident such as powerfailure, etc. occurs, it is desirable to be designed to move the patientoutside the apparatus. Consequently, it is convenient for the headisolating cover 9 to be installed free to open and close, and may beformed with two or more members. In the illustrated example, the headisolating cover is installed free to open and close upwards. The headisolating cover 9 may be formed in part or in whole with transparentsubstrate so that the inside can be seen.

On the surface of the interior panel 6c between infrared ray irradiationsources, a reflection member 8 for reflecting far infrared rays isinstalled. This reflection member 8 is metal, preferably aluminum(including pure aluminum and aluminum alloy) or a substrate covered withaluminum. Examples of a method to use the interior panel surface betweeninfrared ray irradiation sources for the reflection member include (a) amethod for forming a recess or hole on the interior panel, and fittingand mounting the infrared ray irradiation source, (b) a method formounting the infrared ray irradiation source to the interior panelcomponent member different from the reflection member and mounting thereflection member around it, and (c) a method for forming the interiorpanel with aluminum plate and on this panel, installing the infrared rayirradiation source via insulators, heat insulators, etc. of the nearlysame profile of the infrared ray irradiation source as required.

The infrared ray irradiation source used for this apparatus has heatermembers and ceramic members, and these ceramic are formed in such amanner to be fitted to the heater members, so they work to shield nearinfrared rays of wavelength less than 4 μm generated from the heatermembers or to convert them to far infrared rays. As a result, theinfrared ray irradiation source used for this apparatus does not emitnear infrared rays of wavelength less than 4 μm. However, in general,the infrared ray irradiation source has a wavelength in emitted infraredrays, and the probability to contain near infrared rays increases astemperature rises. The infrared ray irradiation source used for thisapparatus is no exception, and therefore, the infrared ray irradiationsource of this apparatus has the wavelength distribution of emittedinfrared rays set to the long wavelength side and at the same time, theheater capacity set to the level required for treatment but to the levelthat does not allow it to contain near infrared rays.

For the ceramic members, zirconia-system, alumina-system, and othermaterials are known, and any of them which can shield near infrared raysof wavelength less than 4 μm is applicable, but it is desirable to usethe material 2 mm or more in thickness.

The human body mounting portion 3 also has the infrared ray irradiationsource which does not irradiate near infrared rays of wavelength lessthan 4 μm. The said infrared ray irradiation source may be composed of aplurality of sources or a single source. The human body mounting portion3 is designed to be formed to slide to the base portion 4 and to bedrawable. Consequently, it is desirable for casters to be equipped.Allowing the human body mounting portion 3 to be slid and drawn out inthis way, the patient can be easily transferred between the stretcherand the infrared ray irradiation apparatus.

The cover portion 1 is formed nearly in a semi-cylindrical profile atthe portion forming the space 5, but it is desirable that the human legside is designed to be formed in a smaller radius.

In the space 5, it is preferable to install two or more fans 12.Installing two or more fans in this way can maintain the air inside thespace to uniform temperature even when a specific portion of the humanbody is irradiated intensively. The temperature inside the space 5should be preferably on the order of 50-80° C., more suitably, from55-65° C.

The human body is irradiated with far infrared rays with the headprotruded from the space 5 to the outside, and the head is preferablycooled during irradiation. Consequently, the head mounting member ispreferably designed to be cooled.

The human body is irradiated and treated with one or more sensorsequipped. The sensor is supposed to measure temperature of each portionof human body, blood pressure, heart rate, and others which arenecessary to check the patient condition. In particular, temperatureinside the human body must be measured, and for example, temperature ofstomach and rectum should be suitably measured.

This infrared ray irradiation apparatus can be controlled by increasingthe intensity of irradiation source to rapidly raise the human bodytemperature to the specified level at the initial stages of irradiationtreatment. By achieving this kind of configuration, treatment time canbe shortened and the number of patients per apparatus can be increased.

EXAMPLE

To the interior panel 6c, a total of 11 or more far infrared rayirradiation sources with the infrared ray irradiation surface measuring10 cm by 23 cm are arranged, namely, 4 or more of them are providedaround the breast portion of the human body, 4 or more of them areprovided around the abdomen portion, 2 or more of them are provided tothe upper leg portion, and one of them is provided to the lower legportion, as well as one piece measuring 52 cm by 1580 cm to the humanbody mounting portion 3.

The heater capacity used for each infrared ray irradiation source isshown as follows:

Heater used for infrared ray irradiation source on interior panel 6c:300 W

Heater used for infrared ray irradiation source on human body mountingportion: 150 W

The reason why the heater capacity used for the human body mountingportion 3 is smaller is that the human body makes direct contact withthe human body mounting portion (cushioning material is used asrequired), and when the distance between the infrared ray irradiationsource and the human body is short and attenuation is small, and asmall-capacity heater is sufficient. In FIG. 3, an infrared rayirradiation source arranged in parallel to the cylindrical shaft isshown, but it is not necessarily arranged in parallel but each infraredray irradiation source may be rotatably equipped. The temperature insidethe space 5 is set to 60° C.±5° C.

ANOTHER EMBODIMENT

For the infrared ray irradiation source, those with construction asshown in FIG. 5 and FIG. 6 may be used. That is, this infrared rayirradiation source comprises a heat generator and an infrared rayirradiation member for being heated with this heat generator andemitting far infrared rays, as well as the heat generation rate by thesaid heat generator is designed to increase more at the circumferentialportion than at the center portion of the said infrared ray irradiationmember.

This far infrared ray irradiation source holds and supports the heatgenerator 24 with both surfaces covered with insulator 22, 23 byrepeating operation to reciprocatedly placing heating wire 21 from oneedge to the other edge in the shorter direction of the heater substrate20 comprising rectangular mica sheets, etc. along the longitudinaldirection as shown in FIG. 5 and FIG. 6 together with the irradiationsheet 26 formed with the insulating plate 25 of the same rectangle andalumina-system ceramics as infrared ray irradiation member. It is builtby being fixed with a retainer plate 27 from the above and mounting alead terminal 18 for feeding power to the heating wire 21 on theinsulating plate 25 side.

In this case, by setting the intervals of heating wires placed nearly inparallel along the shorter direction of the heater substrate 20 narrowerin the vicinity of both edge portions in the longitudinal direction andwider towards the central portion, it is possible to configure that theheat generation rate by the said heat generator is increased at thecircumferential portion than at the central portion of the infrared rayirradiation member. Needless to say, the intervals of heating wires 21narrowed in the vicinity of both edge portions in the longitudinaldirection may be provided on one edge portion only.

For the arrangement of heating wires, in addition to the abovearrangement or separately from the above arrangement, the intervals ofheating wires may be narrowed in the vicinity of both edge portions inthe shorter direction of the heater substrate 20 and widened towards thecentral portion side.

What is claimed is:
 1. An infrared irradiation source comprising a heatgenerator and an infrared ray irradiation member for being heated by theheat generator and emitting far infrared rays not containing nearinfrared rays of wavelength less than 4 μm, wherein a heat generationrate by the heat generator is designed to be greater at acircumferential portion than at a central portion of the infrared rayirradiation member.
 2. An infrared ray irradiation source according toclaim 1, wherein said heat generator is comprised of heating wires,installation density of said heating wires being higher at thecircumferential portion than at the central portion of the far infraredirradiation member.
 3. An infrared irradiation apparatus comprising:ahuman body mounting portion; an operable cover portion comprised of anexterior member, an interior panel and a member containing fillingmaterial provided between said exterior member and said interior panel;and an infrared ray irradiation source comprised of a heat generator andan infrared ray irradiation member for being heated by the heatgenerator and emitting far infrared rays not containing near infraredrays of wavelength less than 4 μm, wherein a heat generation rate by theheat generator is greater at a circumferential portion than at a centralportion of the infrared ray irradiation member.
 4. An infraredirradiation apparatus according to claim 3, wherein a plurality of saidinfrared ray irradiation sources are provided for emitting far infraredrays of wavelength ranging from 5 to 20 μm to the periphery of a humanbody accommodated in a space formed by the human body mounting portionand the operable cover portion.
 5. An infrared ray irradiation apparatusaccording to claim 3, wherein infrared ray irradiation intensity of eachof said infrared ray irradiation sources is independently controlled. 6.An infrared ray irradiation apparatus according to claim 3, whereineleven or more of the infrared ray irradiation sources are provided. 7.An infrared ray irradiation apparatus according to claim 3, wherein analuminum reflecting plate is provided between said infrared rayirradiation sources.
 8. An infrared ray irradiation apparatus accordingto claim 3, wherein a fan is provided inside the space formed by thehuman body mounting portion and the operable cover portion.